書目名稱Genome Editing Technologies for Crop Improvement影響因子(影響力)學(xué)科排名
書目名稱Genome Editing Technologies for Crop Improvement網(wǎng)絡(luò)公開度
書目名稱Genome Editing Technologies for Crop Improvement網(wǎng)絡(luò)公開度學(xué)科排名
書目名稱Genome Editing Technologies for Crop Improvement被引頻次
書目名稱Genome Editing Technologies for Crop Improvement被引頻次學(xué)科排名
書目名稱Genome Editing Technologies for Crop Improvement年度引用
書目名稱Genome Editing Technologies for Crop Improvement年度引用學(xué)科排名
書目名稱Genome Editing Technologies for Crop Improvement讀者反饋
書目名稱Genome Editing Technologies for Crop Improvement讀者反饋學(xué)科排名
作者: 亂砍 時(shí)間: 2025-3-21 22:59
Genome Editing Tools for Food Securityte is not enough. There is a dire need of improving food crops to enhance production and deal with changing climate, reduction in existing water resources and less arable land. Traditional approaches are also being used for improvement in agricultural productivity, but the dawn of genome editing tec作者: 間接 時(shí)間: 2025-3-22 03:23
CRISPR-Cas9/Cpf1-Based Multigene Editing in Cropsnable efficient targeted modification for various trait improvements in crop plants. CRISPR/Cas-based multigene editing in plants is known to edit the targets in various ways that include introduction of alien DNA inserts, generation of knockout mutations and altering of nitrogenous bases via deamin作者: Antecedent 時(shí)間: 2025-3-22 06:10
CRISPR/Cas9 Tools for Multiplex Genome Editing in Crops to improve multiple traits but also for functional analysis of gene families. To solve the problem of delivery of many T-DNAs with separated binary vectors into plant cells at the same time, several approaches have been developed to express multiple gRNA cassettes from a single CRISPR/Cas9 vector. 作者: Ischemia 時(shí)間: 2025-3-22 11:12 作者: Type-1-Diabetes 時(shí)間: 2025-3-22 13:35
Genome Editing in Crops Via Homology-Directed Repair Using a Geminivirus-Based CRISPR/Cas9 Systemough gene knockout (KO) breeding, the next-shifts are focused on the precise gene knock-in (KI) through homology-directed repair (HDR), a DNA repair pathway in which the CRISPR/Cas-induced DNA cleavage is repaired in the presence of homologous repair templates. To facilitate the delivery of these re作者: Type-1-Diabetes 時(shí)間: 2025-3-22 20:21 作者: 盡責(zé) 時(shí)間: 2025-3-22 22:44
Expanding the Scope of Base Editing in Crops Using Cas9 Variantseveloped as novel editing platforms that facilitates specific base modification minus the introduction of double stranded break or homologous recombination. Base editors typically consisted of non-functional CRISPR–Cas9 motif (Cas9 variants) fused with cytosine (CBEs) or adenosine deaminase (ABEs) p作者: 強(qiáng)制令 時(shí)間: 2025-3-23 02:45 作者: padding 時(shí)間: 2025-3-23 08:16 作者: 外表讀作 時(shí)間: 2025-3-23 09:41
Genome Editing Toward Rice Improvementsed mutational and DNA marker-based molecular breeding approaches have contributed enormously toward enhancement of rice productivity. However, it is becoming hard and hard to increase rice yield further due to several factors including a possible ceiling of rice yield potential, the frequent pest a作者: dissent 時(shí)間: 2025-3-23 14:17
Genome Editing Toward Wheat Improvementntial to improve wheat for its economic traits by advanced biotechnologies. As a modern technology with great potential, genome editing has been gradually applied in wheat functional genomic study and breeding with the advancement of wheat genetic transformation system. Among the current genome edit作者: 邪惡的你 時(shí)間: 2025-3-23 21:38
The Use of CRISPR Technologies for Crop Improvement in Maizeenes have been successfully used to improve maize increasing yield and permitting the development of novel herbicide and insect resistance traits. To keep pace with global food demands and promote sustainability, a new technique for improving crops has emerged, genome editing. Here, researchers have作者: extract 時(shí)間: 2025-3-24 00:29 作者: 贊美者 時(shí)間: 2025-3-24 04:23 作者: kyphoplasty 時(shí)間: 2025-3-24 07:04 作者: 有毛就脫毛 時(shí)間: 2025-3-24 12:01
Kaijun Zhao,Rukmini Mishra,Raj Kumar JoshiGeneral information on the recently emerged new biotechnology of genome editing.Practical methods for construction of primary vectors for plant genome editing.Current status of application of genome e作者: MAUVE 時(shí)間: 2025-3-24 15:41 作者: habitat 時(shí)間: 2025-3-24 23:02 作者: conduct 時(shí)間: 2025-3-24 23:41
https://doi.org/10.1007/978-3-030-03979-0te is not enough. There is a dire need of improving food crops to enhance production and deal with changing climate, reduction in existing water resources and less arable land. Traditional approaches are also being used for improvement in agricultural productivity, but the dawn of genome editing tec作者: 不如樂(lè)死去 時(shí)間: 2025-3-25 07:14
Sherenaz W. Al-Haj Baddar,Kenneth E. Batchernable efficient targeted modification for various trait improvements in crop plants. CRISPR/Cas-based multigene editing in plants is known to edit the targets in various ways that include introduction of alien DNA inserts, generation of knockout mutations and altering of nitrogenous bases via deamin作者: 熱烈的歡迎 時(shí)間: 2025-3-25 08:25 作者: 蔑視 時(shí)間: 2025-3-25 11:49
Establishing LCA in the Healthcare Sectorm can induce the cohesive end with a single crRNA and T-rich PAM. Due to the characteristic, the scientists expanded the edit scope and developed the multiplex genes editing system and base editing system by CRISPR-Cpf1. In addition, they increased gene editing efficiency by the single transcription作者: bronchiole 時(shí)間: 2025-3-25 16:53 作者: Reservation 時(shí)間: 2025-3-25 22:17
Educating Thriving Systems Designers,gh efficiency and specificity. For example, the CRISPR-Cas9 system has been extensively used to generate gene knock-out and knock-in mutants of various plant species, because this system can efficiently recognize the targeted site and cause double strand breaks (DSBs), which can be repaired by the e作者: 東西 時(shí)間: 2025-3-26 03:22
Designing Transistor I.F. Amplifierseveloped as novel editing platforms that facilitates specific base modification minus the introduction of double stranded break or homologous recombination. Base editors typically consisted of non-functional CRISPR–Cas9 motif (Cas9 variants) fused with cytosine (CBEs) or adenosine deaminase (ABEs) p作者: Cosmopolitan 時(shí)間: 2025-3-26 07:00 作者: 拖網(wǎng) 時(shí)間: 2025-3-26 11:40 作者: 有機(jī)體 時(shí)間: 2025-3-26 16:22 作者: MUT 時(shí)間: 2025-3-26 16:57 作者: 形狀 時(shí)間: 2025-3-27 01:02 作者: 范圍廣 時(shí)間: 2025-3-27 02:32 作者: 使無(wú)效 時(shí)間: 2025-3-27 07:05 作者: 公司 時(shí)間: 2025-3-27 11:06
https://doi.org/10.1007/978-3-319-47917-0ever, at present the progress of agronomic character improvement through traditional breeding is not enough to meet the growing demand. Thus, to improve soybean breeding through innovative breeding technology is urgently needed. For the past few years, more and more powerful genome editing tools hav作者: Abrupt 時(shí)間: 2025-3-27 17:04
https://doi.org/10.1007/978-981-19-0600-8Genome editing; CRISPR/Cas9; CRISPR/Cpf1; NHEJ; Homologous recombination; Crop Improvement; New biotechnol作者: 符合你規(guī)定 時(shí)間: 2025-3-27 18:50 作者: optional 時(shí)間: 2025-3-28 01:17 作者: MELD 時(shí)間: 2025-3-28 02:37 作者: synovium 時(shí)間: 2025-3-28 07:40
Off-Target Effects of Crop Genome Editing and Its Minimizationch as adjusting single guide RNA (sgRNA) sequence size and limiting its mismatch to a maximum of 3?bp, using proper or engineered endonucleases with higher fidelity and different PAM recognition sites. Also, a more advanced version of delivery mode is suggested, which vector less delivery using ribo作者: 內(nèi)向者 時(shí)間: 2025-3-28 11:30
Genome Editing Toward Rice Improvementde immense potentials to revolutionize the fields of plant science and agriculture. Among the genome editing technologies, the CRISPR/Cas systems are the most widely accepted due to its simplicity, robustness and high efficiency. Rice has been increasingly used to test the efficiency of various type作者: 辮子帶來(lái)幫助 時(shí)間: 2025-3-28 16:02
The Use of CRISPR Technologies for Crop Improvement in Maizeand repair of chromosomal DNA double-strand breaks (DSBs). Using this approach, we first illustrate how two Cas9-induced DSBs can be used to cleanly excise an entire gene to alter starch composition in maize kernels. Next, we show how transgenes can be inserted at Cas9 DSB sites using homology-direc作者: FUSC 時(shí)間: 2025-3-28 19:48
Accelerating Cereal Breeding for Disease Resistance Through Genome Editingerate the cereal-breeding programs. In this chapter, we discuss the recent changes in pathogen populations that pose a challenge to cereal productivity, success stories of disease resistance development in cereal crops through genome editing, potential applications and issues in deployment of genome作者: minaret 時(shí)間: 2025-3-28 23:53
ing tools towards crop improvement. This book will be of particular interest to plant biologists working in the field of genome editing and crop breeders. It will provide valuable information and useful material for our readers’ experimental work.978-981-19-0602-2978-981-19-0600-8作者: Grating 時(shí)間: 2025-3-29 07:04 作者: 手榴彈 時(shí)間: 2025-3-29 10:52
Winning and Noteworthy Competition Schemese been developed to yield the mature gRNA. Optimization of the Cas9 expression promoter is another important approach to further improve multiplex genome editing, and the tissue-specific expression of . leads to the induction of precise mutations with low levels of mosaicism. The development of mult作者: saphenous-vein 時(shí)間: 2025-3-29 14:05
Designing Transistor I.F. Amplifiersd to important agronomic traits in many crops. In this chapter, we have presented a concise idea on the base editing platforms and focused on the application of new ABEs and CBEs with Cas9 variants in crop improvement.作者: Mere僅僅 時(shí)間: 2025-3-29 19:24 作者: Pillory 時(shí)間: 2025-3-29 21:13 作者: extract 時(shí)間: 2025-3-30 03:00
Kwame Nkrumah: Ghana’s Nationalist Iconand repair of chromosomal DNA double-strand breaks (DSBs). Using this approach, we first illustrate how two Cas9-induced DSBs can be used to cleanly excise an entire gene to alter starch composition in maize kernels. Next, we show how transgenes can be inserted at Cas9 DSB sites using homology-direc作者: 雇傭兵 時(shí)間: 2025-3-30 07:52
https://doi.org/10.1007/978-0-85729-372-5erate the cereal-breeding programs. In this chapter, we discuss the recent changes in pathogen populations that pose a challenge to cereal productivity, success stories of disease resistance development in cereal crops through genome editing, potential applications and issues in deployment of genome作者: 漂浮 時(shí)間: 2025-3-30 08:14
Establishing LCA in the Healthcare Sector unit domain with different linkers in plants. So far, the CRISPR-Cas12a system is with higher efficiency, specificity, and easier for gene insertion and large fragment deletion. In this chapter, we summarize the current knowledge of CRISPR-Cas12a system, including found, mechanism, development, application in plants, and prospects.作者: optic-nerve 時(shí)間: 2025-3-30 15:09 作者: Enliven 時(shí)間: 2025-3-30 18:03 作者: intangibility 時(shí)間: 2025-3-31 00:46
Book 2022n about various genome editing tools and their application in major crops. It discusses the genome editing approaches and the strategies used for genome editing in different crops. Some of the chapters cover the detailed methodology of sgRNA design, vector construction and transformation in differen作者: Progesterone 時(shí)間: 2025-3-31 03:28 作者: Toxoid-Vaccines 時(shí)間: 2025-3-31 05:07 作者: Pudendal-Nerve 時(shí)間: 2025-3-31 12:39
https://doi.org/10.1007/978-3-319-47917-0arly interspaced short palindromic repeat) technology in soybean. Meanwhile, we also review its limitations and future utilization potentiality. We believe that future agricultural development will focus on combinations of desirable agronomic traits, and genome editing has huge potential in precision soybean breeding.作者: 刻苦讀書 時(shí)間: 2025-3-31 15:59
Plant Precise Genome Editing by Prime Editingthis chapter, we briefly introduce the advances and potential applications of the PPEs. The efficiency enhancement of PPEs is also discussed, which would be extensively focused on recent research of development of editing tools.作者: 泰然自若 時(shí)間: 2025-3-31 18:14
Genome Editing Towards Sorghum Improvementmes to further improve key phenotypic traits. Current sorghum genome editing techniques have resulted in various trait improvements, such as grain quality. This chapter provides an overview of established and novel methods in sorghum genome editing and transformation, including applications and future directions for sorghum improvement.作者: Arboreal 時(shí)間: 2025-3-31 22:04
Genome Editing Technologies Contribute for Precision Breeding in Soybeanarly interspaced short palindromic repeat) technology in soybean. Meanwhile, we also review its limitations and future utilization potentiality. We believe that future agricultural development will focus on combinations of desirable agronomic traits, and genome editing has huge potential in precision soybean breeding.
